JPH0379005A - Machine for winding multiple air-core coils - Google Patents

Abstract

PURPOSE:To wind multiple coils without cutting a wire of a wound air-core coil by a method wherein a core is freely present and hidden and the side of the air-core coil is rotated to be molded while a pocket is provided on either of a pair of side frames where one of the side frames approaches and separates from the other side frame for containing the air-core coils which have undergone winding. CONSTITUTION:A core 13 is freely present and hidden while the side of an air-core coil is rotated to be molded while a pocket 15 is provided on either of a pair of side frames where one of the side frames approaches and separates from the other side frame for containing the air-core coils which have undergone winding. In this case after the core 13 is made protrude while one of the side frames is made approach the other side frame to wind on the core 13 between both side frames, one of the side frames is separated from the other side frame while the core 13 is pulled in so as to remove from the winding the air-core coil which has been completed with winding. This air-core coil is contained in the pocket 15 without cutting the wire to resume winding. Thus two or more coils can be wound as multiple coils without cutting the wire.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention is directed to a tracking coil made of two or more coils as a set, such as a tracking coil used in an optical pickup for reading signals from an optical information recording disk. The present invention relates to a winding machine that winds a multiple air-core coil in which the air-core coil used is continuous with winding material of an appropriate length without cutting the winding.

[Conventional technology]

Conventional air-core coils, such as tracking coils, which use two or more of the above-mentioned coils without forming a set, were wound using a single-piece winding machine by cutting the winding material at the end of each coil. .

[Problem to be solved by the invention]

In conventional winding machines, if the winding material of the air-core coil that has been wound is not cut, the air-core coil that has been wound will be swung around for the next winding. The winding material coming out of the air-core coil must be cut to an appropriate length.

Therefore, when two or more tracking coils are used as a set like the above-mentioned tracking coils, the cut winding material serving as the terminal must be electrically connected again.

Therefore, it is necessary to provide a board or a land on the board to solder the terminal, which not only requires the board or its space, but also requires a soldering process.

[Purpose of the invention]

In order to solve the above-mentioned problems caused by conventional winding machines, the present invention has been made to install the next air-core coil at the end of an appropriate length of winding material without cutting the winding material of the air-core coil that has been wound. An object of the present invention is to provide a winding machine for multiple air-core coils that can be wound.

[Means to solve the problem]

The above object is achieved by two means of the invention.

First, the winding core can be retracted and retracted, and the winding core rotates to form the side surface of the air-core coil, and one side frame approaches and separates from the other side frame. This is accomplished by providing a pocket that accommodates the core coil.

Second, the winding core can be retracted and retracted, and the side of the air-core coil is molded (rotating, one side frame approaches and separates from the other side frame). A plurality of side frame surfaces are formed on the side frame so as to be able to rotate in a direction perpendicular to the rotation axis of the winding, and to face the other side frame, and on which the winding core can appear and retract on the rotation axis of the winding. This is achieved by

[For production]

In the first means, the winding core is made to protrude, one side frame is brought close to the other side frame, the wire is wound on the winding core between the both side frames, and then one side frame is moved to the other side. The air-core coil is separated from the frame and the winding core is drawn in to remove the finished air-core coil from the winding wire.

This air-core coil is housed in a pocket without cutting its winding material, and winding is performed again in the same manner as described above.

In the second means, one side frame is rotated in a direction perpendicular to the rotation axis of the winding, the side frame surface thereof faces the other side frame, and the side frame surface and the side frame are brought close to each other. After that, winding is performed on the protruding winding core.

When this winding is completed, after separating the side frame from the side frame surface,
One side frame is again rotated in a direction perpendicular to the winding axis, and the other side frame surface is made to face the side frame.

Then, winding is performed in the same manner as described above, and after winding is performed on the winding core on each side frame surface, the winding core is simultaneously pulled in and the air-core coil is taken out.

[Example 1] Next, an example according to the first means will be described with reference to FIGS. 1 to 4.

In FIG. 4, reference numeral 1 denotes a rotating shaft that is rotated via a belt 2 driven by a motor.
A fixed boot I73 and a slide boot I74 that is slidable in the axial direction are provided.

The rotation of the fixed boo U3 is transmitted by the belt 5 to the pulley 8 of the shaft 7 which is supported on the bearing 6, but the bearing 6 does not move.

The slide pulley 4 rotates around the rotating shaft 1 by the action of the cylinder 9.
The rotation is transmitted to the boot IJ 12 of the shaft 11 which slides above and is journalled in a bearing 10 which slides together with this slide.

Inside the shaft 7, a winding core 13 shown in FIG.
The winding core 13 rotates together with the shaft 7.

In FIG. 1, reference numeral 15 denotes a pocket body which rotates together with the shaft 7 and is provided with an arc-shaped pocket 15a for accommodating the finished air-core coil.

A side frame surface 17 is attached to the pocket body 15 by a screw 16 at the center of which the winding core 13 can be inserted and retracted.
A pocket M18 having a hole 18a having substantially the same shape as a and a slotted hole 18b at one end thereof is rotatably attached.

The hole 15b of the pocket body 15 accommodates a ball 19 and a spring 20 that presses the ball 19.
is adapted to fit into the hole 15b and the parallel hole 18c of the concentric pocket M18.

Therefore, the ball 19 is inserted into one of the parallel holes 18c via the pocket M18, and the pocket 15a and the hole 18a are connected to each other.
It is possible to lock them in that position by aligning them, or by fitting them into the other side of the parallel holes 18c to align the blur 15a and the elongated holes 18b.

Further, a pin 21 is provided upright on the pocket lid 18.

On the other hand, as shown in FIG. 4, a side frame 22 is fixed to the shaft 11, and after the winding material is coated with adhesive by rubbing the surface of an adhesive rod 23, the winding material is moved to the core by a guide roller 24. You will be guided towards 13.

This multiple air core coil winding machine first operates the cylinder 9 to bring the side frame 22 close to the side frame surface 17, and then operates the cylinder 14 to move the winding core 13 from the side frame surface 17.
It is made to protrude between the side frames 22.

Then, when the winding material is wound around the winding core 13 and the rotating shaft 1 is rotated, the winding material is wound around the winding core 13 between the side frame 22 and the side frame surface 17. This creates an air-core coil with molded sides.

At this time, before the winding material is guided by the guide roller 24, adhesive is applied with the adhesive rod 23, so when the winding is completed, the adhesive hardens to insulate the wires and prevent the wires from losing their shape. will be held.

In this way, when the winding of one air-core coil is completed, the cylinder 9 is operated in the opposite direction to retract the side frame 22 from the side frame surface 17, and then the cylinder 14 is also operated in the opposite direction. hand,
The winding core 13 is drawn into the side frame surface 17.

As a result, the air core coil can be removed from the winding core 13, and the pocket lid 18 can be rotated to remove the pocket 15a and the hole 18a.
match and open the pocket 15a.

Then, the air core coil that has been wound is placed in the pocket 15a.
After storing the pocket lid 18 in the opposite direction, the pocket 15a is covered with the elongated hole 18b, and the winding material is pulled out from the elongated hole 18b.

Thereafter, if winding is performed in the same manner as described above, the air-core coil accommodated in the finished winding pocket 15a will be transferred to the winding core 1.
3, so the next winding can be done without cutting the winding material.

By repeating the above operation, the required number of air-core coils can be wound in multiple series, but when winding the next wire, as shown in Fig. If the winding material is made to pass through the air-core coils, the length of the winding material between the air-core coils can be increased.

[Embodiment 2] Next, an embodiment of the second means will be described with reference to FIGS. 5 and 6.

In the figure, 30 is a winding shaft corresponding to the rotating shaft 7 of the previous embodiment, 22 is the same side frame as the side frame 22 of the previous embodiment, and its sliding and rotation are performed in the same manner as in the previous embodiment.

An L-shaped rotating frame 31 is fixed to the winding shaft 30, and a shaft 32 extending perpendicular to the winding shaft 30 is rotatably attached to the rotating frame 31.

A side frame 33 having a plurality of side frame surfaces 33a to 33n formed parallel to the axis 32 is fixed to the shaft 32, and a ball 34 and a spring 35 inserted into the hole 31a of the rotating frame 31 cause the recessed portion 33Z of the side frame 33 to be fixed to the shaft 32. is locked and when that locking is done,
Any one of the side frame surfaces 33a to 33n faces the side frame 22.

Winding cores 36a to 36n are retractably inserted into each side frame surface 33a to 33n so as to be concentric with the winding shaft 30 when the side frame surface faces the side frame 22. .

A push-down handle 3B that is biased by a spring 37 and can be pushed down against this bias is housed in the side frame 33 so as to be able to move up and down, and when the push-down handle 3B is pushed down, its slope 38a is The winding cores 36a to 36n resist the elasticity of the silicone rubber 39 that pushes the cores 36a to 36n outward.
It acts so as to draw it into the side frame surfaces 33a to 33n.

This multiple air core coil winding machine has a side frame 33 connected to its shaft 32.
Then, at a position where the side frame surface 33a faces the side frame 22, the ball 34 locks it in the recess 33Z.

Next, in the same manner as in the previous embodiment, after the side frame 22 is brought close to the side frame surface 33a, the winding shaft 30 is rotated to wind the winding material on the winding core 36a.

When the winding is completed, the side frame 22 is retracted from the side frame surface 33a, and the side frame 33 is rotated about the shaft 32 to face the side frame surface 33b. At this time, the rotation of the side frame 33 is as described above. Similarly, it is locked by the ball 34.

Then, in the same manner as described above, winding is performed between the side frame surface 33b and the side frame 22, and this is repeated to form the side frame surfaces 33c to 22.
After forming the winding on 33n, the push handle 38 is pushed down.

Then, the winding cores 36a to 36n are pushed by the slope 38a in the direction of pushing the silicone rubber 39 into the side frame surfaces 33a to 36n.
33n, the air-core coils wound around each of the winding cores 36a to 36n can be removed.

Note that by appropriately setting the angle between the side frame surfaces 33a to 33n, the length of the winding material between the wound air-core coils can be changed.

〔Effect of the invention〕

As described above, the present invention is capable of winding two or more air-core coils in multiple series without cutting the winding material.

Therefore, two or more air-core coils are used, such as tracking coils used in optical pickups that read signals from optical discs such as video discs that record information optically or digital audio discs called compact denoscs. When used as a set connected in series, there is no need to peel off the insulation at the end of the winding material of each coil and solder it to a relay point such as a board, unlike conventional air-core coils.

Therefore, this work is not only unnecessary (substrates, lands, etc. that serve as relay points are also unnecessary, and space can be saved).

Further, the work of winding the multiple air-core coils can be performed in the same manner as the work of winding conventional air-core coils, and the present invention has the characteristics that a partial modification of the conventional winding machine is sufficient.

[Brief explanation of drawings]

1 to 4 show an embodiment of the first means of the present invention, FIG. 1 is an exploded perspective view of the main parts, FIG. 2 is a sectional view of the assembled state, and FIG. 3 is a sectional view of the assembled state. 4 is a front view of the whole, FIGS. 5 and 6 show essential parts of an embodiment of the second means of the present invention, FIG. 5 is a sectional view, and FIG. is a front view. 7.11... Axis, 9. Work 4...Cylinder, 13...
- Winding core, 15... Pocket body, 15a... Pocket, 17... Side frame surface, 18... Pocket lid, 18a.
... Hole, machining 8b ... Elongated hole, rotating frame, 32 ... Side frame surface, 3 Handle, 39

Claims (2)

[Claims] (1) The winding core can be retracted and retracted, and the air core rotates to form the sides of the air core coil, and one side frame approaches and separates from the other side frame. A winding machine for multiple air-core coils, characterized by having a pocket for accommodating the coils. (2) One of the pair of side frames, in which the winding core can be retracted and retracted, rotates to form the side surface of the air-core coil, and one side frame approaches and separates from the other side frame, is used for winding. The side frame is rotatable in a direction perpendicular to the rotation axis, and a plurality of side frame surfaces are formed on the side frame so as to be able to face the other side frame and allow the winding core to appear and retract on the rotation axis of the winding. A winding machine for multiple air core coils.